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/**
 * @file AttitudeControl.hpp
 *
 * A quaternion based attitude controller.
 *
 * @author Matthias Grob	<maetugr@gmail.com>
 *
 * Publication documenting the implemented Quaternion Attitude Control:
 * Nonlinear Quadrocopter Attitude Control (2013)
 * by Dario Brescianini, Markus Hehn and Raffaello D'Andrea
 * Institute for Dynamic Systems and Control (IDSC), ETH Zurich
 *
 * https://www.research-collection.ethz.ch/bitstream/handle/20.500.11850/154099/eth-7387-01.pdf
 */

#pragma once

#include <matrix/matrix/math.hpp>
#include <mathlib/math/Limits.hpp>

class AttitudeControl
{
public:
	AttitudeControl() = default;
	~AttitudeControl() = default;

	/**
	 * Set proportional attitude control gain
	 * @param proportional_gain 3D vector containing gains for roll, pitch, yaw
	 * @param yaw_weight A fraction [0,1] deprioritizing yaw compared to roll and pitch
	 */
	void setProportionalGain(const matrix::Vector3f &proportional_gain, const float yaw_weight);

	/**
	 * Set hard limit for output rate setpoints
	 * @param rate_limit [rad/s] 3D vector containing limits for roll, pitch, yaw
	 */
	void setRateLimit(const matrix::Vector3f &rate_limit) { _rate_limit = rate_limit; }

	/**
	 * Set a new attitude setpoint replacing the one tracked before
	 * @param qd desired vehicle attitude setpoint
	 * @param yawspeed_setpoint [rad/s] yaw feed forward angular rate in world frame
	 */
	void setAttitudeSetpoint(const matrix::Quatf &qd, const float yawspeed_setpoint) { _attitude_setpoint_q = qd; _attitude_setpoint_q.normalize(); _yawspeed_setpoint = yawspeed_setpoint; }

	/**
	 * Adjust last known attitude setpoint by a delta rotation
	 * Optional use to avoid glitches when attitude estimate reference e.g. heading changes.
	 * @param q_delta delta rotation to apply
	 */
	void adaptAttitudeSetpoint(const matrix::Quatf &q_delta) { _attitude_setpoint_q = q_delta * _attitude_setpoint_q; }

	/**
	 * Run one control loop cycle calculation
	 * @param q estimation of the current vehicle attitude unit quaternion
	 * @return [rad/s] body frame 3D angular rate setpoint vector to be executed by the rate controller
	 */
	matrix::Vector3f update(const matrix::Quatf &q) const;

private:
	matrix::Vector3f _proportional_gain;
	matrix::Vector3f _rate_limit;
	float _yaw_w{0.f}; ///< yaw weight [0,1] to deprioritize caompared to roll and pitch

	matrix::Quatf _attitude_setpoint_q; ///< latest known attitude setpoint e.g. from position control
	float _yawspeed_setpoint{0.f}; ///< latest known yawspeed feed-forward setpoint
};